SE509598C2 - Radial Lip Seal - Google Patents

Abstract

A radial lip seal for sealing about a pin of a hinge joint is disclosed. Such seal includes an outer mounting ring, a rubber flex ring mounted inside the mounting ring, a tension ring mounted inside the flex ring, and an inner elastomeric seal ring mounted inside the tension ring. The seal ring has an inside diameter that is a sufficient amount smaller than the pin to cause the tension ring to be stretched by a predetermined amount when the seal is mounted about the pin. The tension ring is capable of exerting a radial force of at least 20 N/cm of circumference on the seal ring upon being stretched the predetermined amount. The unique construction of such a seal is effective in sealing out highly abrasive materials found in very severe operating applications, such as on earthmoving vehicles, and provides a seal having an extremely long service life in such applications.

Description

01 (D \ O (fl \ O (D 2 cleansings in the dressing and an early onset defect in the dressing).

It has been shown that the range of radial force that can be provided by spring seals is insufficient to seal such abrasives in the harsh environments found in earth excavation style applications.

The present invention is directed to eliminating the inconveniences of previous attempts at radial lip seals to provide a sufficiently inward radial force on the sealing lip to seal abrasive contaminants in extremely difficult applications as well as to provide better sealing lip responses at low temperatures.

In accordance with one aspect of the present invention, a high load radial lip seal is provided to seal a cylindrical surface. This lip seal comprises a sealing ring of elongated axial length with opposite ends, a radially projecting sealing lip adjacent one end of the sealing ring and a radially projecting stabilizing lip adjacent the opposite end of the sealing ring and a clamping ring fixed around said sealing ring. Said tension ring is made of a material with sufficient tensile strength module to exert a large radial force of at least 20 N / cm of the circumference along the length of said sealing ring after being stretched to a predetermined elongation factor within a range from about 0.5 % to about 2.5%, and a bending ring fixed around said clamping ring. Said bending ring is made of a highly resiliently resilient, easily deformable material to allow said sealing ring to follow radial and axial displacements of the cylindrical surface to a limited extent. Fig. 1 is a partial cross-sectional view of a hinge joint illustrating a radial lip seal incorporating the principles of the present invention, and Fig. 2 is an enlarged cross-sectional view of the seal itself shown in Fig. 1.

With more reference to the drawings, a radial lip seal applying the principles of the present invention is generally shown at 10 in Fig. 1 together with a hinge joint 12 of the type used on load link devices of packing vehicles and the like (not shown). However, use of the seal 10 is not intended to be limited to pivoting applications, such as in the hinge joint 12, as it is envisaged that the seal 10 is equally suitable for use in any slow rotation application as well as in a shaft bearing box ( not shown), where radial lip seals are used in a typical case, as is well known in the art.

The hinge joint 12 includes a housing 14, through which a pin flange 16 extends. The pin flange 16 is provided with a closed bearing 18 for pivotally bearing a pin 20 extending through the housing 14 and past it. The housing 14 also includes a recess 22 at one end of the barrel 16 for receiving the seal 10. The pin 20 has a cylindrical bearing and sealing surface 24. The hinge joint 12 is lubricated with an oil lubricant (not shown) in a manner well known in the art.

The radial lip seal 10 has a uniform, composite construction and preferably includes a mounting ring 26, a bending ring 28, a clamping ring 30 and a sealing ring 32, all of which are concentrically located relative to each other, the mounting ring being the outermost member, the bending ring 28 is next and is located inside the mounting ring, the clamping ring 13 is located inside the bending ring, and the sealing ring 32 is the innermost member and is located inside the clamping ring.

The mounting ring 26 has a cylindrical design and is preferably made of relatively thin steel pipe material, it being understood, however, that another metal or other rigid material could be used as well. The mounting ring 26 has a final outer diameter with a size which creates a press fit with and which is to be pressed into the recess 22 for the mounting seal 10 in the housing 14.

The bending ring 28 is made of highly resilient resilient and easily deformable material, such as soft rubber with a durometer hardness according to Shore A from 30 to 90 and is the thickest component in order to allow significant axial and radial movements of the pin 20 relative to the housing 14. An oil-resistant synthetic rubber is preferred so that it is not degraded by the oil lubricant in the joint.

The sealing ring 32 is made of a highly abrasion-resistant elastomeric material. A thermoplastic polyurethane is most suitable for the sealing ring 32. The sealing ring 32 has sufficient axial length to accommodate a radially inwardly projecting sealing lip 34 adjacent its outer end 35 and a spaced laterally and radially inwardly projecting stabilizing lip 36 adjacent an inner end 37 thereof. . The sealing ring 32 also includes channel means in the form of at least one and preferably a plurality of channels or grooves 38 through the stabilizing lip to cause lubricant to enter the hinge joint 12 with the sealing lip 34 to lubricate the sealing lip and ensure the presence of lubricant between sealing lips and sealing surface 24 or rotation. The sealing lip 34 is preferably formed with a front angle "F" of about 70 degrees and a half angle "H" of about 20 degrees which provides the sealing lip with a stable geometry under large radial load. The stabilizing lip 36 is preferably provided with similar front and half angles for the same reason and to provide the seal and the stabilizing lip with similar wear and adjustment properties as the sealing lip. The clamping ring 30 is designed as a thin cylinder and must be made of a material with high tensile strength in order to obtain a large belt tension when it is stretched while having an excellent tensile creep resistance so that the belt tension is not lost over time. In particular, the material in the tensioning ring should have a tensile modulus of between 300 and 14000 MPa, with a tensile modulus of about 3000 MPa being preferred, and have a final elongation factor of at least 5%. Such a material should also give a creep of less than 50% for 10,000 hours after being stretched to the elongation factor of 4%.

In its use here, creep means a loss over time in the initial band stress that the stress ring has since it has been stretched to an elongation factor lower than its final elongation. Thus, the material must be suitably joined to the rubber bending ring 28 and to the sealing ring 32. A polyaryl sulfone has been found to be the most suitable material for the clamping ring 30 as it has been found to form a strong polyurethane joint without the use of an adhesive. .

Polyaryl sulfone is available commercially from a number of companies.

In particular, a polyaryl sulfone from Amoco Performance Products, Inc. of Atlanta, Georgia sold under the trade name Radel A100 has been used with satisfactory results.

The seal 10 is manufactured in the following manner. First, the mounting ring 26 and the clamping ring 30 are pre-made individually to a suitable size. The mounting ring 26 of steel can be manufactured in any conventional manner. Preferably, the mounting ring is initially made to a diameter size that is about 15% larger than its final diameter for a purpose which will be explained in the following. The clamping ring 30 is formed by a suitable casting process and is formed to a diameter size which is approximately 2% smaller than its final size when mounted on the pin 20. Thereafter, the rubber is cast in the flange ring 28 between the clamping ring 30 and the mounting ring 26 using a first mold suitable to give the desired shape to the bending ring and by using conventional rubber casting and vulcanization processes. Prior to casting, a suitable joining means is preferably applied to the outer surface of the clamping ring 30 and the inner surface of the mounting ring 26 for fixing the bending ring at the clamping ring 30 and at the mounting ring 26. the clamping ring 30. This is done during the casting process to produce the sealing ring. In this casting process, the clamping ring 30, the bending ring 28 and the mounting ring 26, which have previously been manufactured, are placed together in a second mold which is suitable for producing the desired shape of the sealing ring. Polyurethane is then injected into the mold so that the polyurethane contacts the inner diameter of the clamping ring 30 under sufficient pressure to ensure contact during pressing between them. In general, the contact pressure falls within a range from 17 MPa to about 54 MPa, with about 28 MPa being preferred. The contact usually takes place at a temperature in a range of from about 50 to about 200 degrees C. The contact continues at the above-mentioned temperature and under the conditions for contact under pressure as above for a sufficiently long time to effect the joining of the contacting surface parts. of the sealing ring 32 and the clamping ring 30. Usually the contact time falls in the range of 0.5 seconds to about 20 seconds. In order for the joining of the polyurethane to the polyaryl sulfone to be completely completed, they are kept at an elevated temperature in the range from 90 degrees to 125 degrees C for a sufficient time to cure the polyurethane and thereby strengthen the joining between them. Preferably, the post-curing time falls within a range of from 16 to 24 hours. Using the above method, it has unexpectedly been found that a direct joining of the clamping ring 30 and the sealing ring 32 can be obtained without using an adhesive between them, forming a joint which is strong enough to withstand the stress to which such a seal is subjected. .

Once the seal 10 has been constructed, as described above, the size of the mounting ring 26 is reduced by a suitable countersink operation to its final diameter. The lowering forging is preferably effective in reducing the radial height of the bending ring 28 by about 15%. The purpose of this lowering forging operation is to put the rubber in radial pressure to thereby prevent it from becoming tensioned during use to increase the service life of the rubber bending ring.

Constructed in this way, the sealing lip 34 and the stabilizing lip 36 of the sealing ring 32, respectively, are provided with an inner diameter which is smaller than the outer diameter of the pin 20 to a predetermined extent. As a result, the clamping ring 30 must be stretched to a predetermined extent in order for the seal 10 to be mounted on the pin 20. This stretching creates band tension in the clamping ring 30 which exerts a radial force of at least 20 N / cm at the circumference of the sealing ring 32. This clamping ring can as a rule, exert a radial force of between 50 and 250 N / cm of the circumference with an elongation factor in the range from about 0.5% to about 2.5% of the tension ring, with a range of from about 1% to about 2% being preferred. . As an example, a tension ring of polyaryl sulfone having a diameter of about 55 mm and made of Radel A100 and having an axial width of about 10 mm and a radial thickness of 2.25 mm produced a significant nominal radial force of about 250 N / cm of circumference at the elongation level 1 , 5%. Radel A100 has a final elongation of 6.5%.

It has been shown that by keeping the elongation at the level of 2% or less, creep is kept to a minimum. Thus, a substantially constant force produced by the belt tension on the sealing lip 34 is maintained throughout the working life of the seal 10.

The radial lip seal 20 constructed in accordance with the teachings of the present invention advantageously provides a radial lip seal 10 with much greater lip force than conventional seals so that the sealing lip can prevent the insertion of harmful and highly abrasive materials into the hinge joint 12 or even the entrance. of such materials under the sealing lips themselves.

The construction also enables the lip load to be substantially unaffected by axial or radial movements of the pin 20 relative to the housing 14. The reason for this is that such axial and radial movements are absorbed only by bending the bending ring 28 which is compounded to easily perform such tasks. No lip? or tension ring bending is required for such movements of the pin. Contributing to this is the fact that the seal 10 grips the patch more tightly than all lip seals present in the prior art and in addition resists axial or radial movement of the sealing lip 34 on the pin 20. Hereby the seal 10 can allow significant axial displacements of the pin relative to the housing 28 without any: 509 598 8 accompanying axial movement of the sealing lip 34 on the pin 20.

The sealing lip 34 is thus not subjected to rubbing on exposed portions of the sealing surface 28 of the pin which are likely to be exposed to coarse grains and other highly abrasive materials as is usual with previously existing lip seals.

As previously mentioned, prior art lip seals are located at the end of a cantilever arm. This causes the lip to move in an arc as the pin moves radially.

This arcuate movement of the sealing lip changes the orientation of the lip relative to the pin. Under a large load, the lip can tilt inwards or fold out towards the outside, which eliminates the desired sealing contact with the tap surface 24. Such an arcuate movement of the sealing lip 34 is eliminated in the construction of the present seal, which maintains correct lip orientation of the sealing lip 34 relative to the sealing lip 34. 24. Overflowing or unfolding of the sealing lip is further resisted in the present seal 10 by providing the sealing lip 34 and the stabilizing lip 36 with desired front and half angles. More specifically, each lip has a front angle of substantially 70 degrees and a half angle of substantially 20 degrees relative to the sealing surface 24 of the cylindrical pin. The clamping ring 30 also provides the sealing ring 32 with a stable base so that the sealing lip 34 and the stabilizing lip 36 are kept in the intended orientation relative to the cylindrical surface 24 independently of pin deflections.

As a result of the construction of the present radial lip seal 10, such a seal 10 can have a long service life in the most difficult working conditions with continuous exposure to highly abrasive mixtures of sand, dirt and water of the type found in excavation applications for excavation vehicles.

Other aspects, objects, and advantages of the present invention may be obtained from a study of the drawing, description, and appended claims.

Claims (12)

: S09 598 9 PATENT REQUIREMENTS Radial lip seal (10) for high load to seal a cylindrical surface (24), characterized in that it comprises a sealing ring (32) of extended axial length with opposite ends, a radially inwardly projecting sealing lip (34) adjacent one end of the sealing ring (32) and a radially projecting stabilizing lip (36) adjacent the opposite end of the sealing ring (32), a clamping ring (30) fixed around said sealing ring (32), said clamping ring (30) being made of a material of sufficient tensile strength modulus for exerting a large radial force of at least 20 N / cm of the circumference along the length of said sealing ring (32) after being stretched to a predetermined elongation factor in a range from about 0.5% to about 2.5%, and a bending ring (28) fixed around said clamping ring (30), said bending ring (28) being made of a highly resiliently resilient, easily deformable material to allow said sealing ring (32) to follow radially and axially displacements of the cylindrical surface to a limited extent. Seal (10) according to claim 1, characterized in that said clamping ring (30) exerts a radial force on said sealing ring (32) between 50 and 250 N / cm of the circumference with said elongation factor in the range from about 0 .5% to about 2.5% of said clamping ring (30). Seal (10) according to claim 2, characterized in that said sealing lip (34) and stabilizing lip (36) each have an inner diameter of sufficient size to cause the clamping ring (30) to be stretched to said elongation factor when the seal (10) is mounted around said cylindrical surface (24). Seal (10) according to claim 1, characterized in that the material in said clamping ring (30) is polyaryl sulfone. Seal (10) according to claim 4, characterized in that said predetermined elongation is equivalent to about 2% elongation of said polyaryl sulfone. Seal (10) according to claim 5, characterized in that said sealing ring (32) consists of a polyurethane material. Seal (10) according to claim 6, characterized in that it further comprises a mounting ring (26) fixed around said bending ring (28), the diameter of said mounting ring (26) being reduced to an extent which is sufficient 509 598 10 to keep said bending ring (28) in compression. A seal (10) according to claim 7, characterized in that said sealing ring (32) includes channel means for supplying lubricant to said sealing lip (34). Seal (10) according to claim 8, characterized in that said sealing ring (32) is attached to said clamping ring (30) without any adhesive. Seal (10) according to claim 1, characterized in that the material in said clamping ring (30) has a tensile modulus between 300 and 14000 MPa and a final elongation of at least 5% and is exposed to less than 50 % creep for a period of 10000 hours after being stretched to the elongation factor of 4%. Seal (10) according to claim 10, characterized in that said material in the clamping ring (30) has a tensile modulus of about 3000 MPa and a final elongation of about 6.5% and can provide an initial ring stress which is greater than 150 N / cm of the circumference at the elongation factor of 2%. Seal (10) according to claim 1, characterized in that said sealing lip (34) and said stabilizing lip (36) are oriented for engagement with said cylindrical surface and each have a front angle of about 70 degrees relative to said surface and each has a half angle of about 20 degrees in relation to said cylindrical surface.